460 research outputs found
Direct observation of the glue pairing the halo of the nucleus 11Li
With the help of a unified description of the nuclear structure and of the
direct reaction mechanism we show that a recent 1H(11Li,9Li)3H experiment
provides, for the first time in nuclear physics, direct evidence of phonon
mediated pairing.Comment: 9 pages, 4 figures. Major change
Two-neutron transfer in nuclei close to the dripline
We investigate the two-neutron transfer modes induced by (t,p) reactions in
neutron-rich oxygen isotopes. The nuclear response to the pair transfer is
calculated in the framework of continuum-Quasiparticle Random Phase
Approximation (cQRPA). The cQRPA allows a consistent determination of the
residual interaction and an exact treatment of the continuum coupling. The
(t,p) cross sections are calculated within the DWBA approach and the form
factors are evaluated by different methods : macroscopically, following the
Bayman and Kallio method, and fully microscopically. The largest cross section
corresponds to a high-lying collective mode built entirely upon continuum
quasiparticle states.Comment: 12 pages, 7 figure
Semiclassical Approximation to Neutron Star Superfluidity Corrected for Proximity Effects
The inner crust of a neutron star is a superfluid and inhomogeneous system,
consisting of a lattice of nuclei immersed in a sea of neutrons. We perform a
quantum calculation of the associated pairing gap and compare it to the results
one obtains in the Local Density Approximation (LDA). It is found that the LDA
overestimates the spatial dependence of the gap, and leads to a specific heat
of the system which is too large at low temperatures, as compared with the
quantal result. This is caused by the neglect of proximity effects and the
delocalized character of the single-particle wavefunctions close to the Fermi
energy. It is possible to introduce an alternative, simple semiclassical
approximation of the pairing gap which leads to a specific heat that is in good
agreement with the quantum calculation.Comment: RevteX, 8 Postscript Figure
Study of Giant Pairing Vibrations with neutron-rich nuclei
We investigate the possible signature of the presence of giant pairing states
at excitation energy of about 10 MeV via two-particle transfer reactions
induced by neutron-rich weakly-bound projectiles. Performing particle-particle
RPA calculations on Pb and BCS+RPA calculations on Sn, we
obtain the pairing strength distribution for two particles addition and removal
modes. Estimates of two-particle transfer cross sections can be obtained in the
framework of the 'macroscopic model'. The weak-binding nature of the projectile
kinematically favours transitions to high-lying states. In the case of (~^6He,
\~^4He) reaction we predict a population of the Giant Pairing Vibration with
cross sections of the order of a millibarn, dominating over the mismatched
transition to the ground state.Comment: Talk presented in occasion of the VII School-Semina r on Heavy Ion
Physics hosted by the Flerov Laboratory (FLNR/JINR) Dubna, Russia from May 27
to June 2, 200
Output feedback control of flow separation over an aerofoil using plasma actuators
We address the problem of controlling the unsteady flow separation over an aerofoil, using plasma actuators. Despite the complexity of the dynamics of interest, we show how the problem of controlling flow separation can be formulated as a simple set-point tracking problem, so that a simple control strategy may be used. A robust output feedback control is designed, on the basis of a low-order, linear, dynamical model approximating the incompressible Navier-Stokes equations, obtained from the snapshots of 2D laminar finite element simulations at Re=1,000. Fast flow reattachment is achieved, along with both stabilisation and increase/reduction of the lift/drag, respectively. Accurate 2D finite element simulations of the full-order nonlinear equations illustrate the effectiveness of the proposed approach: good dynamic performances are obtained, as both the Reynolds number and the angle of attack are varied. The chosen output can be experimentally measured by appropriate sensors and, despite its simplicity, the proposed set-point tracking controller is sufficient to suppress the laminar separation bubble; moreover, its extension to 3D turbulent configurations is straightforward, thus illustrating the effectiveness of the designed control algorithm in more practical conditions, which are far from the design envelope
What thermodynamic features characterize good and bad folders? Results from a simplified off-lattice protein model
The thermodynamics of the small SH3 protein domain is studied by means of a
simplified model where each bead-like amino acid interacts with the others
through a contact potential controlled by a 20x20 random matrix. Good folding
sequences, characterized by a low native energy, display three main
thermodynamical phases, namely a coil-like phase, an unfolded globule and a
folded phase (plus other two phases, namely frozen and random coil, populated
only at extremes temperatures). Interestingly, the unfolded globule has some
regions already structured. Poorly designed sequences, on the other hand,
display a wide transition from the random coil to a frozen state. The
comparison with the analytic theory of heteropolymers is discussed
Use of the Metropolis algorithm to simulate the dynamics of protein chains
The Metropolis implementation of the Monte Carlo algorithm has been developed
to study the equilibrium thermodynamics of many-body systems. Choosing small
trial moves, the trajectories obtained applying this algorithm agree with those
obtained by Langevin's dynamics. Applying this procedure to a simplified
protein model, it is possible to show that setting a threshold of 1 degree on
the movement of the dihedrals of the protein backbone in a single Monte Carlo
step, the mean quantities associated with the off-equilibrium dynamics (e.g.,
energy, RMSD, etc.) are well reproduced, while the good description of higher
moments requires smaller moves. An important result is that the time duration
of a Monte Carlo step depends linearly on the temperature, something which
should be accounted for when doing simulations at different temperatures.Comment: corrections to the text and to the figure
On the Excitation of Double Giant Resonances in Heavy Ion Reactions
The interplay of nuclear and Coulomb processes in the inelastic excitation of
single- and double-phonon giant resonances in heavy ion collisions is studied
within a simple reaction model. Predominance of the Coulomb excitation
mechanism on the population of the single-phonon and, on the contrary,
predominance of the nuclear excitation for the double-phonon is evidenced. The
effect of the spreading of the strength distribution of the giant resonances on
the excitation process is analyzed, showing sizeable modifications in the case
of Coulomb dominated processes.Comment: Accepten in Nuclear Physics A. 10 eps figures and source file in an
uncompressed tar packag
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